DE1177721B - Hydraulic drive linkage for electrical switches - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Boarding school Cl .:

H02c

GERMAN

PATENT OFFICE

EDITORIAL

German KI .: 21c -40/51

Number:
File number:
Registration date:
Display day:

S 74116 VIIId / 21 c

May 26, 1961

September 10, 1964

Hydraulic drive linkages for switches are known. They consist of a piston that goes into a cylinder is movable. The piston is moved by pressure fluid, for example pressure oil acts z. B. a lever on the switch shaft. Switches must be switched quickly. Man therefore does not use a pump that feeds the pressure fluid, for example the pressure oil, into the working cylinder promotes, but you can see one for the delivery of the hydraulic fluid into the cylinder Energy storage, which is slowly charged by the pump. Such an energy store exists for example from a vessel filled with liquid in which gas is compressed under pressure will.

For rapid switching, the masses to be moved must be accelerated strongly at the beginning and then at the end decelerated according to the movement. For this task there is a constant pressure in the cylinder of the well-known hydraulic linkage is not ao suitable, because it would reduce the masses to be moved not only give the desired uniform acceleration at the beginning, but also during the Accelerate all the way. You therefore have in the line, which the hydraulic fluid from Accumulator leads into the cylinder, a throttle point built in (or the cross-section of the line selected to be correspondingly small), so that with an increase in speed of the piston, the pressure in the cylinder drops. This achieves that the pressure in the desired Way and thus the force acting on the piston decreases at the end of the path and that the devices required to brake the moving masses at the end of the switching path are not closed grow up. The flow of hydraulic fluid through the throttle causes a loss of energy, which must be applied by the memory.

According to the invention, this energy loss can be avoided in that as hydraulic Drive linkage two pistons of different cross-sections with associated cylinders are provided and that one of the pistons is connected to the cylinder belonging to the other piston. It moves First of all, the piston with the large diameter moves, which results in a large initial acceleration will. After the end of its stroke, the small piston then moves, while only the small one Supplies work to complete the switching movement. You therefore get the desired dependency the force acting on the masses to be moved without throttling as with the known hydraulic drives is necessary.

Hydraulic drive linkage
for electrical switches

Applicant:

Siemenß-Schuckertwerke Aktiengesellschaft,

Berlin and Erlangen ^ -

Erlangen, Werner-von-Siemens-Str. 50

Named as inventor:

Paul Duffing f>

Henry Burmestef, Berlin

While with the known hydraulic drives, each unit of length of the piston travel is always the same Volume is removed from the memory, the linkage according to the invention will stop the movement of the large piston only has a relatively small volume per unit of length of the piston path enmoTMnren.'Kleinefe volume removal but means less energy is drawn off at constant pressure in the storage tank.

It is useful when the piston is connected to the cylinder belonging to the other piston is, with this one piece. Advantageous a through hole is given to this piston wedge, which forms the cylinder for the other piston forms. This also has the advantage that there is only one supply line.

You can use a linkage for switching on and a spring or for switching off also a hydraulic linkage. Appropriately, one becomes in the line to the storage container of the energy storage install a throttle point. This is advantageous because the backward movement of the hydraulic linkage is initially only slight There must be damping, because initially only the small piston goes back, and as a result only a small amount of oil will flow through the small cross-section of the throttle point. if However, when the large piston goes back at the end of the movement, a correspondingly large volume of oil must be used flow through the throttle point, and there is a correspondingly large damping. This choke point thus replaces the otherwise usual danish institution, such as oil pumps, friction brakes, etc. working on flow resistances. This has an effect particularly advantageous if you have a hydraulic for both switching on and off

409 660/380

Linkage used according to the invention, since then always one linkage for the other The movement generated by the linkage acts as a damping effect, which initially only marginally, on the other hand, counteracts the The end of the movement is large in the desired manner. The hydraulic linkage is particularly useful in connection with a storage tank in which the storage vessel is filled with hydraulic fluid, d. That is, the memory contains no gas, and the energy impact 30 on the cylinder 5. Now postpones the large piston 2 in the cylinder 3 up to the position shown. This uses a much larger amount of oil pressed by the throttle point 16 into the reservoir, this creates a damping the switch-off movement on the last distance in the desired manner.

The memory 11 consists of a tube 32 with the welded-on cover 33 and the other

Storage takes place by compressing the io welded bottom 34. He is completely with

Liquid and optionally filled by the elastic oil and has a at its topmost point

Evaluation of the vessel takes place. opening closed by a screw 36 so that

In the drawing, three exemplary embodiments are shown to allow air to escape when the container is filled with oil

of the invention shown. can. The container is via a check valve 38

In Fig. 1, the hydraulic linkage is connected to 1 with the oil pump 18. This is signed into action. It consists of a piston 2 which can be set when the pressure in the energy store is inappropriate Cylinder 3 and piston 4 falls below a certain value, it stops working

Diameter with the associated cylinder 5. The cylinder 3, which has a stroke-limiting stop 6 is rigidly connected to the piston 4 by the screws 7. For supplying the cylinders two movable lines 8 and 9 are provided with pressurized oil. These two moving lines are on the one hand to work via a line 10 when the nominal pressure is reached again.

You can also let the cylinder 5 attack the lever 21 via the bolt 29 and the piston 22 store on the axle 24.

Fig. 2 shows another embodiment of the invention. Here is the large cylinder 3 on the Axis 24 rotatably mounted. The large piston 2 and

Memory 11, on the other hand via a line 12 with 25 of the small cylinder 5 consist of one piece. Connected to the storage container 13. In each of the piston 4 is rotatably mounted on the bolt 29, the last-mentioned lines is a valve 14 or has the extension 30 a. The large cylinder 3 has 15. A throttle point 16 is incorporated into the line 12, the stop 6. The other parts, which are built with those of the, at whose point the cross-section of the line 1 also coincides, are with the same pressure 12 can be reduced accordingly. The 30 train marks are provided. Here too, the

Reservoir is connected in a known manner via a line 17 to the pump 18, which the Memory 11 is charging.

The switch shaft 20 is switched on by a lever 21 first of the large piston 2 in the cylinder 3 until its movement is limited by the stop 6. The accelerating force is on the cylinder 5 and the stop 30 α

moves, on which the piston 2 with the piston 35 the bolt 29 transferred. After the arrival of the Kolstange 22 attacks. The cylinder 5 is fixed around the 2 on the stop 6, the piston 4 moves

in the cylinder 5, which is now stationary, and ends the movement with a small force. When switching off only the small piston 4 moves in the cylinder 5

Standing shaft 24 pivotably-mounted. To the lever 21 also engages an opening spring 26. With 27 and 28 are stops for the movement of the lever

21 denotes, the stop 27 in known 40 and then the large piston 2 in the cylinder 3. The

Has a dampening effect. The mode of operation is the same as with the arrangement

according to FIG. 1. Also in the arrangement according to FIG. 2, the piston 4 can be supported on the axis 24 and the cylinder 3 on the bolt 29.

The mode of operation is as follows: It is assumed in the drawing that the switch is in the off position stands. To switch on the valve 14

open, the valve 15 is closed. After 45 minutes nothing changes
tion of the valve 14 initially moves the large figure. 3 shows a further embodiment. at

the arrangement according to FIG. 3, the piston 2 is stepped and has a through hole 5 α.

Piston 2 in the cylinder 3 up to the stop 6. It accelerates the moving parts with great force Masses and partly tensioned the opening spring

26, which is relaxed in the switch-off position. After an agitation 50 ben4. This "piston 4 carries an approach 30 α. The end of the movement of the piston 2 in the cylinder 3 cylinder 3 in which the piston 2 moves

a stop 6 α and is loaded on the axis 24

This hole is the running surface for the little KoI-

the piston 4 is moved in the cylinder 5. He takes the cylinder 3 and the piston 2 with and ends the switch-on travel of the lever 21 with a small force and thereby further tensions the switch-off spring 26. In the switched-on position, the switch is held in place by a pawl 31 in a known manner. then the valve 14 is closed and the valve 15 is opened.

When switching off the latch is released, and the opening spring 26 leads the lever 21 into the one shown Location back. The small piston 4 moves to the right in the cylinder 5 and takes the large cylinder 3, the piston 2 of which does not initially move relative to this. So it will A small amount of oil is driven through the throttle point 16 only by the piston 4. At the end of the movement of the piston 4, this is supported with an

gert. The piston 4 is rotatably mounted in a bolt 29 of the double-armed lever 21 a. Two stops 27 and 28 limit the movement of the lever 21 a. Only one movable supply line 8 is provided, which is connected to the reservoir via a line 10 in which the valve 14 is located and to the storage container 13 via a line 12 in which the valve 15 is located.

At the other end of the lever 21 α , a hydraulic linkage, which is constructed on the same principle, engages. The corresponding parts are provided with the same reference numerals, only with the index '. One linkage switches on, the other linkage switches off.

To hold the switch in each of its two end positions, a locking lever 40 or 40 'and a

Rast 41 and 41 'are provided. The locking lever 40 or 40 'is pivotable about the axis 42 or 42' and is pressed into the detent by a spring 43 or 43 '.

If the lever 21 α is to be moved from the position shown (switch-on position) into the other position (switch-off position), the valves 14 and 15 'are opened when the valves 15 and 14' are closed. It now flows from the memory 11 via the line 10 pressure oil into the large cylinder 3, and the piston 2 is moved forward and takes the lever 21 a with it after opening the catch 41. At the same time, the small piston 4 'is pressed into the small cylinder 2'. The small volume of oil which flows through the throttle 16 'to the reservoir has only an insignificant damping effect, so that the force generated by the piston 2 is available almost exclusively to accelerate the moving masses of the switch. In the further course of the movement, the large piston 2 rests against the stop 6 a , and the small piston 4 now moves in the cylinder bore of the large piston 2 in the working direction, with only a small force being transmitted to the switch shaft 20 . If in the course of the movement the extension 30'a comes into contact with the large piston 2 ', this is pressed into the cylinder 3'. As a result, a large amount of oil is pressed into the reservoir via the throttle point 16 ', and a large amount of damping is produced. The movement of the switch is thus strongly damped, but continued until the lever 21 a rests against the stop 28. The latch 40 'then engages and the valves 14 and 15' are closed.

If it is to be switched off, the valves 14 'and 15 are opened and the upper hydraulic linkage moved in the working direction. First the large piston (2 ') and then the small piston (4') are moved. In the case of the lower hydraulic linkage, the small piston 4 is first and then the large piston 2 moves. The mode of operation is the same as described earlier for switching on.

The diameter of the pistons and their strokes will be chosen so that the optimum switching speed is achieved is achieved. The piston strokes of one hydraulic linkage can be different choose large and also the other's strokes and piston diameters different from those choose the former. The choice depends on the requirements for switching it on and off be asked.

Claims (5)

Patent claims: 1. Hydraulic drive linkage for electrical switches, characterized in that it consists of two pistons (2, 4) of different cross-sections with associated cylinders (3, 5) and that one of the pistons (4) with the cylinder belonging to the other piston (2) (3) is firmly connected (Fig. 1). 2. Hydraulic drive linkage according to claim 1, characterized in that one of the Piston (2) forms a unit with the cylinder (5) belonging to the other piston (4) (Fig. 2). 3. Hydraulic drive linkage according to claim 2, characterized in that the one Piston (2) has a through hole (5 a) that holds the cylinder for the other piston (4) forms (Fig. 3). 4. Hydraulic drive linkage according to claim 1, characterized in that both a hydraulic linkage is provided for switching on as well as for switching off. 5. Hydraulic drive linkage according to claim 1, characterized in that in the line A throttle point (16) is built into the reservoir. 1 sheet of drawings 409 660/380 9.64 © Bundesdruckerei Berlin